Generating Fano Resonances in a Single-Waveguide Silicon

Oct 22, 2018 - The rapidly increasing demand for optical interconnects leads to the .... (b) Transmission spectra (from plane 2 to plane 3 in Figure 1...
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Generating Fano Resonances in a single-waveguide silicon nanobeam cavity for efficient electro-optical modulation Jianhao Zhang, Xavier Leroux, Elena Duran Valdeiglesias, Carlos Ramos, Delphine Marris-Morini, Laurent Vivien, Sailing He, and Eric Cassan ACS Photonics, Just Accepted Manuscript • DOI: 10.1021/acsphotonics.8b00867 • Publication Date (Web): 22 Oct 2018 Downloaded from http://pubs.acs.org on October 23, 2018

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Generating Fano Resonances in a single-waveguide silicon nanobeam cavity for efficient electro-optical modulation Jianhao Zhang, †,§ Xavier Leroux, † Elena Durán-Valdeiglesias, † Carlos Alonso-Ramos, † Delphine Marris-Morini, † Laurent Vivien, † Sailing He, *,§ and Eric Cassan*,† †

Centre for Nanoscience and Nanotechnology (C2N), CNRS, University Paris-Sud, University Paris-Saclay, 91405 Orsay cedex, France

§

Centre for Optical and Electromagnetic Research, Zijingang Campus, Zhejiang University, Hangzhou 310058, China

KEYWORDS: Fano photonic crystal cavity, asymmetric lineshape, spatial-division multiplexing, subwavelength optics, mode mixing, electro-optical modulation

ABSTRACT: A method for generating Fano resonance in a standalone silicon nanobeam cavity is reported and investigated thoroughly. The proposed approach eliminates the inconvenience from the unexpected side-coupled bus waveguide of previous Fano cavity geometries and

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unlocks new opportunities to develop ultra-compact and ultra-fast silicon electro-optical modulators. Taking advantage from a spatial-division multiplexing principle of operation between transverse electric modes, a sharp resonant mode and an efficient flat background mode are simultaneously generated in the same silicon channel for the realization of efficient Fano resonances. Unambiguous asymmetric spectral lineshapes are experimentally demonstrated in the near infra-red around λ=1.55µm correlated to analytical and numerical methods. The best identified mode for optical modulation presents an extinction ratio of 23 dB for a ∆λ =366 pm wavelength detuning while its Q factor is limited to only 5600. For the same wavelength detuning, this extinction ratio is ∼14 dB higher than the one of the classical Lorentzian cavity exhibiting the same Q factor. Electro-optical modulation based on the silicon Fano cavity and exploiting the plasma dispersion effect is proposed and quantitatively studied, showing roman energy consumption as low as few fJ/bit. The overall gathered results show that the proposed Fano-cavity scheme addressed in this paper presents an interesting potential for low-power consumption silicon electro-optical modulation and provides new insight to the advantages and applications of Fano resonances in nanophotonics.

The rapidly increasing demand for optical interconnects leads to the strong requirement of ultralow power consumption and tens-to-hundreds-gigabits devices, among which silicon optical modulators play an essential role. Micro-resonators including micro rings/disks and photonic crystal cavities, which feature small footprint and relatively small driven signal for high extinction ratio1 (e. g. up to 15dB), have been found to be a promising solution to enable on-chip silicon modulators2-7 and compact integrated photonic switches8-10. However, to ease the burden

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from the considerable photon lifetime in a ultra-high-quality factor (Q) cavities, which would be detrimental to the target modulated bandwidth, resonators designed for high bit rate modulators have usually limited Q factors of a few thousands. This sacrifice on Q factors results in a larger power consumption of tens to hundreds of femtojoules per bit5,11,12 for acceptable extinction ratio (>∼8 dB). Approaches like different-signal driving13 and vertical P-N structures14 for silicon disk resonators have been implemented to reduce power consumption. However, these kinds of doping schemes are complex and challenging with respect to fabrication accuracy control. Therefore, new and simple solutions are expected for low power consumption and high-bit rate optical modulation. In this context, Fano resonances, which arise from the interference of a discrete resonant mode and a continuum background15, present an efficient ON/OFF transition in a more reduced wavelength detuning between maximum reflection and maximum transmission, than the classical Lorentzian-kind cavities of similar quality factors. This specific behavior can be used to address the bandwidth-power trade-off of silicon resonant optical modulators and potentially minimize the power consumption of silicon switching and modulation devices. Different types of Fanoresonance-based cavities have already been proposed including spatial membrane structures16, plasmonic resonators17 and integrated side-coupled one/two-dimensional (1/2D) photonic crystal cavities18-21. Thanks to the advances of fabrication technology, novel integrated devices based on these Fano cavities like nonreciprocal transmission structures22, Fano lasers23 and switches24 have been demonstrated. Especially, an all-optical high-bit rate modulation behavior combining the free carrier response of indium phosphide and a Fano cavity was demonstrated24,25. Among earlier demonstrated integrated Fano cavities, most of previous structures consist of a bus waveguide and a side coupled photonic crystal cavity18-21. When implemented with photonic

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wires, e.g. within a nanobeam cavity scheme, a first drawback of such configurations arises from the high sensitivity of the bus waveguide/cavity region optical coupling ratio on the technological fabrication imperfections of the structure (in particular on the width of the bus waveguide)26. The second stems from the fact that the cross-sectional structure of the modulator is intrinsically both asymmetric and more extensive than a simple waveguide one, which complicates the realization of the doping profiles of the PN junction and increases both the capacitance of the whole structure and the access resistances to the polarization electrodes. The obstacle to the realization of fast active cavities based on PN junctions is not related to the realization of the junction itself. The flexible use of P-N junctions27 was indeed demonstrated in a 2D photonic crystal active cavities but this excellent work did not exploit the specifically steep spectral signature of Fano optical cavities, leaving a field of investigation for further progress in terms of power consumption and modulation speed. For the full exploitation of the Fano signature of active cavities, it is particularly important to look for fully integrable configurations in a single waveguide (strip or strongly engraved rib). In this direction, Fano resonance was observed in a single nanobeam cavity28, but Fano generation mode mixing between interfering channels was only made at the collection fiber level stage, degradation of Fano generation was observed with the fiber location, and design methodology for flexible and systematic Fano generation process still remain unsolved. Targeting these issues, we address here the investigation of the combination of nanoresonators and control electrodes to develop a new class of Fano resonance silicon modulators aiming at a dramatic reduction in power consumption without sacrificing bandwidth. Design, fabrication and characterization of sharp and effective Fano resonances in a simple standalone waveguide structure for optical switching and modulation is reported. The mechanism adopted for realizing

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an effective Fano resonance in a single waveguide geometry without any side-coupled bus waveguide17-25 is initially introduced, then followed by the systematic investigation of the behavior and robustness of Fano spectra by both theoretical and experimental characterizations. Our analysis, stemming from analytical and quantitative analysis, gives new insight to the advantages of Fano resonances for optical modulation schemes, and indicates room for further optimization. Though sacrificing the capability for extending to more bus/cavity channels, our cavity effectively compresses the physical dimensions of a Fano cavity and provides room to design P-N junctions nearly as easily as in a single wire waveguide. Combining with rib nanobeam structures27, 29 or nano-arms-assisted nanobeam resonators30, the reported new Fano cavity scheme can be expanded for developing low-power consumption optical modulators based on the plasma dispersion effect. PRINCIPLE As it is well known, a Fano resonance arises from the interference between a discrete resonance and a continuum22, and can be practically implemented in a planar photonic platform by placing a side-coupled bus waveguide (the “continuum”) to the vicinity of a photonic cavity (the “discrete resonance”) whose coupling and decay rates are controlled by a small partially transmitting element (PTE), as illustrated in Fig. 1 (a). Compared to this classical configuration in which the resonant and transmitting modes are generated in different physical channels and manipulated by the PTE, the method we propose here is to take advantage of a two-mode spatial multiplexing scheme to generate the resonant and the transmitting modes in the same physical optical waveguide, as shown in Fig. 1 (b). This standalone Fano cavity consists of a single-mode input waveguide, a nanobeam cavity which cross section supports two transverse electric-field (TE) propagating modes (position 2), and a subwavelength mode mixer. The TE1 andTE2

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propagating modes, which are schematically depicted by the blue/red dash curves in bottom left inset of Fig. 1 (b), have symmetric/asymmetric fields within the waveguide cross-section, respectively. The Multimode Interference (MMI)-like operation allows a tight control of the balance between the excited TE1 and TE2 propagating modes at position 2 through the choice of

the narrow (input) and wide (nanobeam) waveguides’ widths, labelled  and  , respectively (see Fig. 1 (b)). The key of the design is also to widen the contrast between the effective indices of these two modes so that the TE1 propagating mode strongly feels the influence of the cavity,

thus generating a marked spectral resonance, while the second propagating mode TE2 is only slightly sensitive to the periodic corrugation of the waveguide geometry and thus presents a very flat transmission spectrum (i.e. an ultra-wide resonance). The spectrum of both TE propagating modes are schematically represented by the solid curves in Fig. 1 (b) at position 3. The nanobeam cavity is followed by a subwavelength mixer for inter mixing between the TE1 propagating mode narrow resonance and the TE2-mode wide resonance, respectively, which produces two Fano resonances, i.e. for each of the TE modes. An additional narrow side waveguide forms a directional coupler to convert the TE2 propagating mode to the TE1 mode of the side waveguide (see the left inset of Fig. 1 (b)). Five planes marked by black dash lines (1,2, 3, 4, and 5) at different positions in Fig. 1 (b) are used to illustrate the structure principle of operation: plane 1 at the input waveguide, plane 2 before the cavity, plane 3 before the mode mixer, plane 4 after the mode mixer, and plane 5 at the bifurcation of the output directional coupler.

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Figure 1. (a) Schematic of a classical integrated Fano cavity.  and  are the decay rates due to

cavity modes-waveguide modes coupling. (b) Schematic of the proposed standalone Fano cavity, consisting of a MMI-like input structure, a nanobeam cavity, a subwavelength mixer and a directional coupler. The blue and red dashed curves represent the spatial mode profiles (bottom right inset) of the TE1 and TE2 propagating modes, respectively. The blue and red solid curves

represent the spectral lineshapes of the TE1 and TE2 propagating modes, respectively. Top right inset: the propagating distribution of the TE2 propagating mode coupled with and converted into the TE1 mode of the side waveguide. Middle right inset: zoom-view of the 3-slit subwavelength mixer and the propagating distribution corresponding to a TE1 mode injection.

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In order to study the feasibility of the proposed single-waveguide principle of operation, eigen mode solving and FDTD methods were extensively used to calculate the mode dispersion and field and power transmission levels of the TE modes in the nanobeam structure. The corresponding platform we considered starts from a typical silicon-on-insulator (SOI) photonic platform with a 220nm thick silicon core and a 2μm thick buried silicon dioxide layer. The dispersion curves of both TE propagating modes (at plane 2) obtained for different nanobeam widths (wn) are presented in Fig. 2 (a). In principle, in order to provide a high transmission level for the TE2 mode with a weak perturbation from the nanobeam cavity, the difference of effective index values between the TE1 andTE2 propagating modes should be as large as possible to prevent Bragg reflection for the TE2 mode. A waveguide width wn=630 nm (neff,TE1~2.55 and neff,TE2~1.6) corresponds to the ideal value but due to the rapid change of the TE2 propagating mode dispersion close to this condition, this option can lead to fabrication-sensitivity issues.

Thus, a moderate value  =800nm was selected (throughout this work), providing an acceptable

index contrast between the TE1 and TE2 propagating modes of ~ 0.565.

Figure 2. (a) Dispersion curves of the TE modes at 1550nm wavelength in a 220nm-thick silicon on insulator strip waveguide with different width values (wn) (plane 2 in Fig. 1 (b)). (b) Transmission spectra (from plane 2 to plane 3 in Fig. 1 (b)) of the TE1 and TE2 propagating modes through a classical nanobeam cavity with wn=800nm, 50 holes and 300nm period. (c) Transmission spectra of the TE1 and TE2 propagating modes through the proposed Fano cavity

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with a 400nm-wide input waveguide. The period, filling factor and length of the subwavelength holes array are Pe=200 nm, ff=0.5 and Le=400nm, respectively. Other parameters are identical to that reported in (b). In each figure, the TE1 and TE2 propagating modes are depicted by blue and red curves solid lines or circles, respectively. Structures corresponding to the (b) and (c) configurations are shown in the insets, in which the TE1 and TE2 spatial mode profiles are displayed in blue and red dash lines, respectively. Next, a nanobeam cavity with a 50-holes array under a period of 300nm was considered. To obtain a resonant high quality (Q) factor and a high transmission for the TE1 mode, the hole radii were tapered from 100nm in the center to 70nm in a 15-periods length31. Extra 10-holes mirror sections with identical 70nm radius holes were added at the end of each taper. The total length of

the nanobeam cavity was close to 15 μm. The calculated transmission spectra (from plane 2 to

plane 3 in Fig. 1 (b)) for both TE propagating modes are shown in Fig. 2 (b). The simulated

quality factor/transmission values with TE1 input (merely TE1 propagating mode in the nanobeam waveguide) for the 1st and 2nd cavity modes are 230000/55%, and 19000/95%, respectively. For the TE2 propagating mode, an average transmission larger than 90% is obtained in the 1500nm to 1600nm wavelength range. Though the peak transmission of these two TE propagating modes are not exactly balanced, the related excitation ratio can easily be engineered by adjusting the input waveguide width of the MMI-like structure to find the right balance between the two optical modes. To mix both TE propagating modes after the nanobeam cavity (plane 4 in Fig. 1(b)), a subwavelength mixer consisting of few asymmetrically-located rectangle-shape etch holes (Fig. 1 (b)) is placed after the resonator. The period, filling factor, and length of the mixer region hole are Pe=200 nm, ff=0.5 and Le=400nm, respectively. Both TE propagating modes in the nanobeam

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waveguide excite the first two order modes of the subwavelength structure, which are converted back into the TE propagating mode again after the mixer. By carefully selecting the mixer length, we achieve a TE1-TE1 and the TE2-TE1 mixing efficiency of ~45% and ~35%, respectively. These coupling efficiencies are obtained here from a 3-N (3 holes) subwavelength mixer (optimizing methodology for the subwavelength mixer is presented in supplementary materials). The simulated propagating distribution corresponding to a TE1 light injection is shown in the middle right inset in Fig. 1 (b). The mode interference behavior after the subwavelength mixer is an obvious signature of multimode generation. The transmission levels of the TE propagating modes through the complete device (inset in Fig. 2 (c), i.e. from plane 1 to plane 4) including the input waveguide width wi=400nm (which provides excitation efficiencies of 55% and 40%, for TE1 and TE2 mode, respectively), the MMI-like structure, the nanobeam cavity, and the subwavelength mixer, are reported in fig. 2(c). Unambiguous Fano line spectra for the TE1 propagating mode (blue curve in Fig. 2 (c)) and the TE2 mode (red curve in Fig. 2 (c)) are observed, which confirms the adequate interference of the resonant and the flat spectra. Interestingly and as it could be anticipated, the TE2 mode (red curve in Fig. 2 (c)) also exhibits a Fano spectrum lineshape, since part of the TE1 and TE2 modes are indeed coupled back to the TE2 mode as well after the mixer. Uncomplete destructive interferences marked by the appreciable but not complete Fano dips (transmission does not drop to 0) result from the unbalanced TE1/TE2 energy levels. Each of both Fano resonance behaviors can be separately optimized by adjusting either the TE1-TE1, TE2-TE1 mixing efficiencies or the TE2-TE2, TE1-TE2 ones. ANALYTICAL DESCRIPTION OF FANO RESONANCE

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To further study the generation of Fano resonances in such a standalone cavity structure, we performed complementarily analytical calculation using the temporal coupled-mode theory18, 32 (TCMT). The equivalent schematic view of the cavity dynamics is shown in Fig. 3 (a). The total

structure can be considered as a two-port scattering system. , are the forward and backward field amplitudes from port I (left side port), respectively. and share the same definitions for port II (right side port).  is the complex transmission coefficient of electric field (then

 = | | is the power transmission) of the TE1 propagating mode after the mixer (energy of

TE1 mode in plane 4 normalized to that at plane 1). For a nanobeam cavity with a resonant

angular frequency  and corresponding electric field  for the TE1 mode, the decay rate for

this resonant mode due to coupling to the two feeding waveguides, the decay rate due to out-of-

plane scattering and intrinsic absorption are , ,  ,  , respectively. Therefore, the total decay rate (TE1 propagating mode) can be written as  =  + +  +  . The energy excitation

efficiency from TE1 propagating mode to the TE1 and TE2 modes in the MMI-like structure (defined in Fig. 2 (b)) are labeled by  and  , respectively. Meanwhile the efficiencies from the

TE1 and TE2 modes to the TE1 mode of the subwavelength mixer at the output port are labelled

as  and  , respectvely. The transmission of the nanobeam cavity for the TE2 propagating

mode called  ( = | | ) can be assumed as nearly uniform due to the weak interaction of this mode with the array of patterned holes.

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Figure 3. (a) Schematic of the dynamics of optical waves in a standalone two-port waveguide nanobeam Fano cavity. TE1 and TE2 propagating modes are marked by blue and red dashed curves, respectively. The spectrum of TE1 and TE2 propagating modes are depicted by the blue and red curves, respectively. (b), (c) The transmission of the TE1 mode versus the varying

excitation efficiencies  ,  and mixing efficiencies  ,  . The exchange efficiencies in (b) are fixed as:  = 0.45, C = 0.35, while the excitation efficiencies in (c) are:  = 0.55 and

 = 0.45 , respectively. Both (b) and (c) share the following parameters:  = 2π ∗ 193.414(), T2= 90%, * =

+,

-,

= 7 / 100 , * =

+,

-1

= 1.6 / 103 and * =

4,

-5

6 30000.

According to the TCMT and considering a detuning of angular frequency 78 =  9 , the

coupled equations of the resonant and backward waves can be written as follows:

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:; :=

=  + @2 A BC, @

= DE @ + @2 A BC, 

(1)

(2)

= @2 A BCF @ + @  @ ?A B∆C

(3)

in which H and H are the phase factors of the cavity waveguide modes at the left and right

ports, respectively. ∆H is the phase difference between the TE1 and TE2 propagating modes, which is counted from the MMI-like interface to the front plane of the mixer. The reflection

coefficient of the nanobeam cavity mirrors for the TE1 mode is DI , which can be considered as 1 for simplification (Confirmed by an estimated reflection power level at slightly off-resonant wavelength which indicated a reflection coefficient ∼0.98). For steady state condition, da(t)/dt=0 and the field transmission coefficient for the TE1 mode

through the whole structure ( = | | ) can be written as:

 = KKM = J JL K

@-, -F N, O,, P Q BST -5

+ ?@   A B∆C

(4)

For symmetric cavity design, H = H ,  =  , and for a highly confined cavity mode, A B = cos + ? sin = 9DE 6 91, 23 therefore

 =

L JKK

JKM

6

-, @N, Z,, BST -5

+ ? @ [  A B∆C

(5)

If there is no excitation of the TE2 mode and no mixer region after the cavity (  = [ = 1,  =  = 0), then

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,  = |= | 6 SF F

0-F

T

5

(6)

The total transmission of the TE1 propagating mode then goes back to a typical Lorentzian shape. For a case where  ≠ 0,  ≠ 0:  6

LF], @N, O,, ]5 ^ B T  ]5

 6 a =

+ ?@   A

LF], @N, O,, ]5 F ^T  ]F 5

f]F ,N O , ,, ]F 5 F ^T  ]F 5

+

B∆C

=

F], ^ @N, O,, _B ]T ` ]5 5 ^F T  ]F 5



F], @N, O,, ]5 ^F T  ]F 5

9 @   b?c∆H d + a

  

f], = @N, O,, NF O,F ]5 F ^F T  ]F 5

+

+ ?@   A B∆C

ST -5

(7) 

+ @   [eb∆H d

(8)

g T [eb∆H + b?c∆Hh S

-5

Assume that the phase relative variable is written as i = 9

ST -5

+

ST -5

[eb∆H + b?c∆H, we simplify

Tt as:  6

   j

=   

f]F , k, l,, F ]F 5 kF l,F 5F F ^T  ]F 5 F

F] @k l ^ _ T , , ,, ` ]5 ]5 5F @kF l,F ^F T  ]F 5

Assuming that

ST -5

= ϵ,

+

^F T  ]F 5 ^F T  ]F 5

+

f], @k, l,, ]5 5F @kF l,F ^F T  ]F 5

+   

-, @Np O,,

-5 =F @NF O,F

_

g -T + i hm S

5

f], @k, l,, On ` ]5 5F @kF l,F F ^T  ]F 5

(9)

= q, and taking into account that the total energy of the TE2

propagating mode coupled back to TE1 mode is  =   [, we can simplify A(10) as:

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= 6 

F r F 

+ 

t sOn u r F 

(10)

The first term of equation (10) is the same as the traditional expression for Fano resonance in a two-port cavity33. The variable q is the asymmetric parameter, which quantifies the Fano spectrum asymmetry. The normalized energy amplitude of the continuum part of the TE1

propagating mode, e.g. the  , becomes the amplitude coefficient of the Fano spectrum in Eq. (2). Similarly the classical Fano spectrum in which the amplitude coefficient is the transmission

of the partially transmitting element15. However, the above equations indicate that the phase quantity also contributes to the transmission and can cause a small deviation to the perfect Fano

line shape. By controlling i , this phase related item can be minimized and high quality Fano

lineshapes can then be obtained. As a whole, the above analytical calculation shows that the obtained pseudo Fano expression opens room to design a sharp Fano-like behavior. Analysis for TE2 mode can be made similarly and is not shown here. To study the effect of excitation efficiencies and mixing efficiencies to the spectrum, we

assume that ∆H = 0 (then i = ϵ + b?c∆H =0) for simplification, thus: = = 

F r F 

+  rF  

(11)

Based on equation (11), we accordingly adjust the energy ratio of the TE1/TE2 propagating modes and the mixing efficiencies to search the optimization operation point. The related details are shown in Figs. 3 (b) and (c). In these plots, clear Fano curves presenting sharp spectral

transitions and high extinction ratio are demonstrated from  = 0.1 and  = 0.9. The best configuration for Fano behavior, indicated by q 6 1 (the largest asymmetry), is generally linked

to the most rapid change (maximum slope) of the structure spectral transmission. This condition

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is satisfied here when  = 0.55, as shown in Fig. 3 (b). Especially, the comparison between the

 = 0.9 and  = 0.999 cases shows that values of  close to 1 are necessary to recover a Lorentzian shape cavity spectral lineshape.

We also investigated the effect of the mixer with different coupling efficiencies ( and

 > on the Fano spectra, as shown in Fig. 3 (c). The q parameter variation is much more limited than in the previous case and the spectra keep a fairly marked Fano shape even in the severe

 ;  = 70%;5% condition, which indicates the robustness of the proposed Fano cavity

scheme against variations of the mixer geometry. Overall, the main trends reported in Fig. 3 (b)

and (c) provide a design strategy to target a trade-off between correct Fano lineshapes and large extinction ratio values. EXPERIMENTS The scanning electron microscopy (SEM) picture of a typical fabricated device is shown in Fig. 4 (a). The gap (Fig. 1 (b)) between the nanobeam waveguide and the side waveguide

(ws=400nm) is here of 150nm. A straight coupling length of 16 μm was chosen to completely

couple the TE2 propagating mode in the nanobeam waveguide to the TE1 mode in the side

waveguide. Then the side waveguide was turned into a bend waveguide with a radius of 40 μm

for an ultra-low loss separation of both modes. The performances of this directional coupler were

confirmed by 3D-FDTD simulations and from many fabricated devices characterizations. The mixer dimensions consisted of 3 rectangle etched holes with a 200nm period and a 50% filling

factor, each rectangle hole having a length (zP in Fig. 1 (b)) of half { , i. e. of 200nm. The width of the input waveguide was chosen as 500nm since the experimental transmission of resonant

mode was usually lower than the theoretical one. Other parameters about the nanobeam cavity

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were directly inherited from the design stages. i.e. a nanobeam waveguide width { =800nm, N=50 (number of holes), and a hole radius profile quadratically tapered from 100nm in the center

to 70nm at the edges.

Figure 4. (a) SEM views of fabricated devices. The MMI-like structure and subwavelength mixer are shown in the top-left and bottom-right insets, respectively. (b) Experimental transmission of the nanobeam waveguide. (c) Experimental transmission around 2nd cavity mode detected in nanobeam and side waveguides, depicted by blue and orange curves, respectively. (d) Experimental transmission and fitting curve of 1st cavity mode of nanobeam waveguide, depicted by blue circles and orange curve, respectively. (e) Experimental transmission and fitting curve of 2nd cavity mode of nanobeam waveguide, depicted by blue circles and orange curves, respectively. Lorentzian curve is labeled by a green curve while transition between maximum and minimum are depicted by grey regions.

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The transmission curves of the full structure are shown in Fig. 4 (b). Clear Fano lineshapes for the 1st and 2nd order cavity modes are observed, with resonance wavelengths located at around 1515 nm and 1531 nm, respectively, which are close to the values (1510nm and 1533nm) obtained from 3D-FDTD simulation in Fig. 2 (b). Simulated distributions for these two modes are presented in the insets of Fig. 4 (b). Simultaneous Fano lineshapes of the 2nd cavity mode in the nanobeam and side waveguides are also shown in Fig. 4 (c), as the blue and orange curves, respectively. Zoomed-in views of the transmission curves of the around the two spectral resonances are shown in Fig. 4 (d) and (e), respectively. The blue circles and the orange solid curves are experimental results and fitting curves from Eq. (10), respectively. In Fig. 4 (d), we see that in a wavelength detuning of 56pm, the cavity optical transmission experiences a transition drop of about 17 dB. To experimentally obtain the quality factor, another device with same parameters but an input width of 700nm was further analyzed. This wide-input device can be considered as a classical nanobeam cavity without any TE2 propagating-mode excitation (Fig. 2 (b)). According to our previous analysis, the transmission spectrum is then

pretty close to a Lorentzian resonance. Using * =

∆+ +|

, a Q factor of ~32000 was obtained (the

transmission of this Lorentzian spectrum is low and not shown in Fig. 4 (d)). The Q factor value was also extracted from Eq. (10), by fitting the experimental Fano spectrum. The asymmetric

total decay rate  was 2π ∗ 2.96GHz, which indicated a Q factor of 34000, well coincident with that given by the Lorentzian-kind device. The asymmetric parameter q was estimated as

q=1.6335, i.e. close to the perfect Fano condition (i. e. |q|≈1) proving the consistency of the carried-out optimization. In addition, the total measured energy transmission from the TE2

propagating mode to the TE1 one ( =   [ ) was found around 0.1267. Considering the

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excitation ratio of TE2 mode ( ) for a 500nm width input waveguide of about 0.3 and the nanobeam transmission ( ) of 0.9 and a mixing efficiency ([ ) of 0.35, this value of 

(0.1267) is thus in good agreement with analytical prediction (0.0945).

Similar analysis for the 2nd cavity mode was performed as well from which a more than 23.2 dB extinction ratio was obtained for a wavelength detuning of 366pm, as shown in Fig. 4 (e).

The calculated asymmetric parameter q, the Q factor and the total transmission  were 1.894,

5600 and 0.1056, respectively (the phase variables i for both cases were calculated to be close

to zero and are not shown). Using a device made of an identical nanobeam cavity but with a 700nm-width input waveguide, an overall transmission T=0.88 was experimentally monitored. According to the estimation31  = _

€55‚ƒ €„…



` and the classical relationship



€55‚ƒ





„…





QM1

,

quality factors *†‡ and *B ˆ , both accounting for waveguide coupling and intrinsic absorption

and vertical losses were estimated as *†‡ =5930 and *B ˆ =100000, respectively. This estimate

thus demonstrated the negligible nature of optical losses by absorption and out of plane scattering. An experimental Lorentzian spectrum with nearly the same Q-factor of 5600 is reported as well (green curve) in Fig. 4 (e) for comparison, which is clearly less efficient. For a lossless Lorentzian resonance

-5F

F -5F

with the same Q factor of 5600 ( =2π ∗ 17.75GHz),

the Extinction Ratio (ER) for a wavelength detuning of 366pm (∆ 6 2π ∗ 46.83GHz) is 10log(

-5F

F -5F

>=9dB. This value is 14dB smaller than that of the experimentally reported Fano

resonance (∼23dB). From another perspective, with the same Q factor (5600) and ER (23 dB),

the wavelength detuning required in a Lorentzian case is 1.96nm (∆ 6 2π ∗ 251GHz), which

would lead to a much higher driven power. Increasing Q is obviously an option to ease the

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burden from ER-frequency detuning trade-off e.g. A Q as high as 40000 in Lorentzian-spectrum cavity is capable of providing the same efficiency, however such a high Q would lead to an excessive photon lifetime, raising an obstacle to the bandwidth of electro-optical modulators

based on this structure11. For example, for a quality factor of only 10000, the bandwidth Š‹Œ limited by photon lifetime in already no more than 20GHz, according to



F Ž‘

=  +

 and ’ = . These comparisons indicate the excellent potential of the proposed single•Z ”€

waveguide Fano cavities (Q∼5600) for ultra-fast, efficient electro-optical modulation and switching.

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Figure 5. (a) Excitation efficiencies of the TE1 and TE2 propagating modes at plane 2 in a nanobeam waveguide with wn=800 nm, connected with an input waveguide with different widths wi ranging from 300-700nm. (b) The corresponding mode overlap between the input waveguide and nanobeam waveguide. (c)-(j) Evolution of the Fano spectrum by varying the width of the input waveguide wi from 300nm to 700nm, respectively. In order to have a clear observation on how Fano resonance is influenced by the balance between modes, a series of configurations with different TE1/TE2 excitation ratios was

performed by varying the input waveguide width B . As shown in Fig. 5 (a), with the nanobeam

width { being fixed at 800nm (again, throughout this work), the out(plane 5)/in(plane 1)

excitation efficiency of the TE1 propagating mode, increases with the waveguide width, while the excitation efficiency of the TE2 mode first reaches a maximum at B =400nm, and then

gradually decreases with increasing B values. These monotonous trends of the TE1 mode curve

can be understood with the related increased effective index value which minimizes the impedance mismatch between the input access waveguide and the nanobeam waveguide modes. On the other hand, the increased TE2-mode efficiency arises from an improved effective index matching and the largest mode overlap (Fig. 5 (b)) at the input/nanobeam waveguide interface. Fig. 5 (a) indicates that the excitation efficiency of the TE1/TE2 mode can be adjusted in a large range (from nearly 55%/40% to infinity). For input waveguide widths larger than 400nm, the summation of the TE1 and TE2 excitation efficiencies (i. e. the summation of blue and red curves in Fig. 5 (a)) is close to 1, which also indicates an available width range for low-loss light injection. The spectrum evolution of an array of fabricated Fano cavities with different B

ranging from 300 nm to 700 nm is reported in Fig. 5 (c)-(j). The spectrum lineshapes first behave as all-pass filters and become asymmetric with increasing input waveguide widths and achieve

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almost a maximum asymmetry within the range of 500-600 nm of input waveguide width, then coming back to an add-drop-type Lorentzian shape resonator at wi≈700 nm. Clear Fano lineshapes are widely observed from wi=450nm to 650 nm. This easiness highlights the robustness of our design even in the case of possible tens of nanometers of fabrication errors. DISCUSSION Remembering that the limited quality factor (for high bit rate modulation) in a Lorentzian active cavity puts a practical ceiling to the extinction ratio and tends to increase the needed operating voltage swings (usually up to few volts2), the most important merit of Fano resonance resonators is to improve the extinction ratio and power consumption by providing a sharp transition between reflection and transmission states. Since our design is intrinsically suitable for P-N modulator and switching integrated schemes, one significant further work is here to estimate the power consumption of electro-optic modulators r relying on the plasma dispersion effect and the proposed standalone Fano resonator.

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Figure 6. Proposed Fano modulator based on rib silicon P-N depletion structure. Inset is the cross-section of the rib structure at the position labeled by dot line. The proposed P-N Fano modulator is shown in Fig. 6. and the analysis is performed on the 220nm SOI platform with 170 rib thickness and 50 nm slab thickness. The Fano cavity is slightly doped in both side and a depletion region formed in the center. Meanwhile, the free carriers induced index change in silicon can be described at 1.55µm wavelength by34: ∆c = ∆cP + ∆c– = 9[8.8 / 10  / ∆˜P + 8.5 / 10 ™ / š.™

(12)

∆cP , ∆c– , ∆˜P and ∆˜– are here the electron induced index change, hole induced index change,

the density changes of electrons, and density change of holes. For a common doping change level of ∆˜P = ∆˜– = 5/ 10› , the index change is ∆c= 91.7 / 10 ‹ . We consider a nanobeam

cavity with symmetric P-N junctions, i. e. with identical widths for the P-type and N-type regions. The optical index in the P doped/depletion regions can be considered as 3.4783 and ~3.48, respectively. Since the depletion width of the P-N junction can be described as35: œ: = 

ž| žT s

g£¤ + £P¥= 9

¦‘ § s



© 

(13)

ªš = 8.8542 / 10  «/­ and ª8 = 12 , £¤ , £P¥= and q are the vacuum silicon dielectric

constant, the silicon dielectric constant, the build-in potential, external applied voltage and the unit charge. ®¯ is the Boltzmann constant and  is the temperature fixed at 300K.

For a 0.35nm shift of the Fano resonance (consistent with the 2nd cavity mode discussed above, with Q~5600 and an extinction ratio larger than 20dB), the required width change of the depletion region calculated by using 3D-FDTD simulation was estimated to ACS Paragon Plus Environment

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about 15c­. The peak-peak voltage for such a width change at a bias of £¯ 6 90.5£ is

∆£P¥= 6 0.5£ (i. e. £P¥= is within the range of£¯ 9 ∆£P¥= /2 to to £¯ + ∆£P¥= /2). Considering

an average depletion width of 100nm and a cavity length L=15²­, the capacitance of the P-N junction is35: : = ªš ª8

³TQ´ ¶

z 6 4f«

(14)

Therefore the energy consumption per bit can be estimated to11: ¸=

F O∙ˆnn

0

=

O ∙∆ˆ F 0

6 0.25Š¹/º?

(15)

Even considering a practical capacitance (i.e. an experimental capacitance taking other capacitance and fabrication imperfection into account besides the depletion capacitance) of C=50fF like for earlier reported ring resonators15, the energy consumption per bit is still as low as 3.125Š¹/º? . Such a low energy consumption per bit, which is supported by the small

wavelength detuning of 366pm required to obtain an ER of 23dB in the proposed Fano cavity with a low Q factor of 5600 is not possible to be achieved in Lorentzian-lineshape resonant

modulators. For the 1st cavity mode of Q~34000, (0.056nm shift for ER>15dB), the energy

consumption per bit is reduced down to ¸ 6 0.5Š¹/º?. Besides, asymmetric doping profiles

could be further considered to optimize the active structure performances36. The absorption resulting from the free carriers31 we obtained for this structure is ∆α = 7.25cm  , from which

we derived an imaginary part ( c = c + ?® , at 1550nm wavelength) of refractive index of

∆® = 0.89 / 10 0 . Taking this value into account, we recalculated the quality factor of the nanobeam cavity with and without free carriers. The quality factor for the 2nd cavity mode in the

passive case being 1.89 / 100 , while it was estimated to 1.29 / 100 when free carriers were ACS Paragon Plus Environment

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accounted for, indicating an additional decay rate of only ∆ =2π ∗ 2.38GHz. Comparing this value to the experimental total decay rate of the 2nd mode ( =2π ∗ 17.75GHz), we observe that

the impact of free-carrier absorption on the Fano resonance decay is small. This result brings a confirmation that the cavity quality factor is dominated by the strong coupling30 between the propagating mode in the feeding waveguide and the cavity mode, rather than by free-carrier

absorption losses (i.e., with the notations of the paper, the resonance is mainly governed by ,

,  , rather than  ), let alone the further lossy contribution from fabrication. Thanks to this

small additional decay rate, q is only weakly influenced by free carriers so that the asymmetric spectral lineshape of the cavity is preserved in the active modulation configuration. CONCLUSION In this paper, clear and marked Fano resonance is achieved in a single-waveguide silicon nanobeam cavity, which provides a novel path to develop monolithically integrated high-frequency and low power consumption silicon modulators. By using the mode-diverse response of a single nanobeam cavity, controlling the spatial-division multiplexing and mode mixing in the multimode waveguide section, we realize a sharp resonant mode and a flat background mode in the same silicon channel for flexible generation of Fano resonances. Unambiguous asymmetric spectrum lineshapes were experimentally observed, presenting 23.2 dB extinction ratio within 366 pm detuning for one of the cavity mode (Q=5600), which factors of merits cannot be reached in classical Lorentzian-kind integrated active cavities of similar Q factors controlled with the identical wavelength detuning. Our investigation based on an analytical model supported by quantitatively numerical calculation, reports a thoughtful strategy for the optimization of the pseudo Fano resonances. The energy consumption of active modulation in a

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single-waveguide Fano cavities using the plasma dispersion effect was estimated to be less than few fJ/bit, giving competitive potential to the realization of low power consumption silicon optical modulators operating at high-data bit rates (>>1Gbits s-1). We believe that the proposed Fano cavity scheme opens a room for the realization of single-waveguide silicon modulators going beyond the current state of the art. METHODS Fabrication and Characterization. A silicon-on-insulator (SOI) wafer with 220nm silicon thickness was used for fabrication. Device fabrication was based on Electro-Beam lithography, ICP-RIE etching and wet cleaning process37. A tunable laser (Yenista TUNICS – T100S) operating in the 1520-1640nm wavelength range, a polarizer, and a power meter (Yenista CT400), were used for charactering the devices. A couple of grating couplers are used for fiberchip in and out interfacing. All the transmission curves are normalized to straight waveguides with identical grating couplers.

ASSOCIATED CONTENT Supporting Information The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acsphotonics. Xxxxxxx. Principle, optimization and robustness of subwavelength mixer

AUTHOR INFORMATION

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Corresponding Author *E-mail: [email protected] Author Contributions J. Z. designed the devices, performed calculation and simulation, characterized the samples. X. L. R. and E. R. V. and C. A. R. fabricated the samples. D. M. M. and L. V. provided guidance in analyzing. J. Z. and E. C. wrote the manuscript with input from everyone. E. C. and S. H. supervised the work. Notes The authors declare no competing financial interest. Funding Sources The French ANR agency is also acknowledged for the its support through the SITQOM project.

ACKNOWLEDGMENT We thank China Scholarship Council for supporting this work. The French ANR agency is also acknowledged for the its support through the SITQOM project.

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(2) Xu, Q.; Schmidt, B.; Pradhan, S.; Lipson, M. Micrometre-scale silicon electro-optic modulator. Nature. 2005, 435, 325-327. (3) Manipatruni, S.; Preston, K.; Chen, L.; Lipson, M. Ultra-low voltage, ultra-small mode volume silicon microring modulator. Opt. Exp. 2010, 18, 18235-18242. (4) Dong, P.; Liao, S.; Liang, H.; Qian, W.; Wang, X.; Shafiiha, R.; Feng, D.; Li, G.; Zheng, X.; Krishnamoorthy, A. V.; Asghari, M. High-speed and compact silicon modulator based on a racetrack resonator with a 1 V drive voltage. Opt. Lett. 2010, 5, 3246-3248. (5) Tanabe, T.; Nishiguchi, K.; Kuramochi, E.; Notomi, M. Low power and fast electro-optic silicon modulator with lateral p-i-n embedded photonic crystal nanocavity Opt. Exp. 2009, 17, 22513. (6) Nguyen, H. C.; Hashimoto, S.; Shinkawa, M. and Baba, T. Compact and fast photonic crystal silicon optical modulators. Opt. Exp. 2012, 20, 22465-22474. (7) Terada, Y.; Kondo, K.; Abe, R.; Baba, T. Full C-band Si photonic crystal waveguide modulator. Opt. Lett. 2017, 42, 5110-5112. (8) Soref, R.; Hendrickson, J. R.; and Sweet, J. Simulation of germanium nanobeam electrooptical 2 × 2 switches and 1 × 1 modulators for the 2 to 5 µm infrared region. Opt. Exp. 2016, 24, 9396-9382. (9) Zhou, H.; Qiu, C.; Jiang, X.; Zhu, Q.; He, Y.; Zhang, Y.; Su, Y.; Soref, R. Compact, submilliwatt, 2 × 2 silicon thermo-optic switch based on photonic crystal nanobeam cavities. Photonics Research 2017, 5, 108-112.

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(10) Soref, R. Tutorial: Integrated-photonic switching structures. APL Photonics 2018, 3, 021101. (11) Dong, P.; Liao, S.; Feng, D.; Liang, H.; Zheng, D.; Shifiiha, R.; Kung, C.-C.; Qian, W.; Li, G.; Zheng, X.; Krishnamoorthy, A. V.; Asghari, M. Low Vpp, ultralow-energy, compact, high-speed silicon electro-optic modulator Opt. Exp. 2009, 17, 22484-22490. (12) Rosenberg, J.; Green, W. M. J.; Assefa, S.; Gill, D. M.; Barwicz T., Yang, M.; Shunk, S. M.; Vlasov, Y. A. A 25 Gbps silicon microring modulator based on an interleaved junction. Opt. Exp. 2012, 20, 26411-26423. (13) Zortman, W. A.; Lentine, A. L.; Trotter, D. C.; Watts, M. R. Low-voltage differentiallysignaled modulators. Opt. Exp. 2011, 19, 26017-26026. (14) Timurdogan, E.; Sorace-Agaskar, C. M.; Sun, Jie.; Hosseini, E. S.; Biberman, A.; Watts, M. R. An ultralow power athermal silicon modulator. Nat. Comm. 2014, 5, 4008. (15) Miroshnichenko, A. E.; Flach, S.; Kivshar Y. S. Fano resonances in nanoscale structures. Review of Modern Physics 2010, 82, 2257-2298. (16) Zhou, W.; Zhao, D.; Shuai, Y.-C.; Yang, H.; Chuwongin S.; Chadha, A.; Seo, J.-H.; Wang, K. X.; Liu, V.; Ma, Z.; Fan, S.; Progress in 2D photonic crystal Fano resonance photonics. Progress in Quantum Electronics 2014, 38, 1-74. (17) Limonov, M. F.; Rybin, M. V.; Poddubny, A. N.; Kivshar, Y. S.; Fano resonance in photonics. Nat. Photon. 2017, 11, 543-554. (18) Fan, S. “Sharp asymmetric line shapes in side-coupled waveguide-cavity systems,” Appl. Phys. Lett. 2002, 80, 908-910.

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(19) Yu, P.; Hu, T.; Qiu, H.; Ge, F.; Yu, H.; Jiang, X.; Yang, J. Fano resonances in ultracompact waveguide Fabry-Perot resonator side-coupled lossy nanobeam cavities. Appl. Phys. Lett. 2013, 103, 091104. (20) Heuck, M.; Philip, Kristensen, P. T.; Yuriy, E.; Mørk, J. Improved switching using Fano resonances in photonic crystal structures. Opt. Lett. 2013, 38, 2466-2468. (21) Nozaki, K.; Shinya, A.; Matsuo, S.; Sato, T.; Kuramochi, E.; Notomi, M. Ultralowenergy and high-contrast all-optical switch involving Fano resonance based on coupled photonic crystal nanocavities. Opt. Exp. 2013, 21, 11888. (22) Yu, Y.; Chen, Y.; Hu, H.; Xue, W.; Yvind, K.; Mørk, J. Nonreciprocal transmission in a nonlinear photonic-crystal Fano structure with broken symmetry,” Laser & Photon. Rev. 2015, 9, 241-247. (23) Yu, Y.; Xue, W.; Semenova, E.; Yvind, K.; Mørk, J. Demonstration of a self-pulsing photonic crystal Fano laser. Nat. Photon. 2017, 11, 81-84. (24) Yu, Y.; Heuck, M.; Hu, H., Xue, W.; Peucheret C.; Chen, Y.; Oxenløwe L. K.; Yvind, K.; Mørk, J. Fano resonance control in a photonic crystal structure and its application to ultrafast switching. Appl. Phys. Lett. 2014, 105, 061117. (25) Yu, Y.; Hu, H.; Oxenløwe, L. K.; Yvind, K.; Mørk, J. Ultrafast all-optical modulation using a photonic-crystal Fano structure with broken symmetry. Opt. Lett. 2015, 40, 23572360.

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(26) Fegadolli, W. S.; Pavarelli, N.; O’Brien, P.; Njoroge, S.; Almeida, V. R.; Scherer, A. Thermally Controllable Silicon Photonic Crystal Nanobeam Cavity without Surface Cladding for Sensing Applications. ACS Photon. 2015, 2, 470-474. (27) Shakoor, A.; Nozaki, K.; Kuramochi, E.; Nishiguchi, K, Shinya, A.; Notomi, Compact 1D-silicon photonic crystal electrooptic modulator operating with ultra-low switching voltage and energy Opt. Exp. 2014, 22, 28623-28634. (28) Mehta, K. K.; Orcutt, J. S.; Ram, R. J. Fano line shapes in transmission spectra of silicon photonic crystal resonators. Appl. Phys. Lett. 2013, 102, 081109. (29) Sodagar, M.; Miri, M.; Eftekhar, A. A.; Adibi, A. Optical bistability in a one-dimensional photonic crystal resonator using a reverse-biased pn junction. Opt. Exp. 2015, 23, 26762685. (30) Zhang, J.; He, S. Cladding-free efficiently tunable nanobeam cavity with nanotentacles. Opt. Exp. 2017, 25, 12541-12551. (31) Quan, Q.; Loncar, M. Deterministic design of wavelength scale,ultra-high Q photonic crystal nanobeam cavities. Opt. Exp. 2011, 19, 18529-18542. (32) Suh, W.; Wang, Z.; Fan. S. Temporal Coupled-Mode Theory and the Presence of NonOrthogonal Modes in Lossless Multimode Cavities. IEEE JOURNAL OF QUANTUM ELECTRONICS 2004, 40, 1511-1518. (33) Yoon, J. W.; Magnusson, R. Fano resonance formula for lossy two-port systems,” Opt. Exp. 2013, 21, 17751-17759.

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(34) Soref, R. A.; Bennett, B. R. “Electrooptical Effects in Silicon,” IEEE JOURNAL OF QUANTUM ELECTRONICS. 1987, 23, 123-129. (35) Zhou, Y.; Zhou, L.; Zhu H.; Wong, C.; Wen, Y.; Liu, L.; Li, X.; Chen, J. Modeling and optimization of a single-drive push–pull silicon Mach–Zehnder modulator. Photon. Res. 2016, 4, 153-160. (36) Marris-Morini, D.; Vivien, L.; Fédéli, J. M.; Cassan, E.; Lyan, P.; Laval, S. Low loss and high-speed silicon optical modulator based on a lateral carrier depletion structure. Opt. Exp. 2008, 16, 334-339. (37) Hoang, T. H. C.; Duran-Valdeuglesias, E.; Alonso-Ramos, C.; Serna, S.; Zhang, W.; Balestrieri, M.; Keita, A.-S.; Caselli, N.; Biccari, F.; Le-Roux, X. R.; Filorama, A.; Gurioli, M.; Vivien, L.; Cassan, E. Narrow-linewidth carbon nanotube emission in silicon hollowcore photonic crystal cavity. Opt. Lett. 2017, 42, 2228-2231.

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TOC Graphic (For Table of Contents Use Only)

Generating Fano Resonances in a single-waveguide silicon nanobeam cavity for efficient electro-optical modulation Jianhao Zhang, †,§ Xavier Leroux, † Elena Durán-Valdeiglesias, † Carlos Alonso-Ramos, † Delphine Marris-Morini, † Laurent Vivien, † Sailing He, *,§ and Eric Cassan*,† An ultra-compact single-waveguide Fano cavity is proposed by exploiting an original spatialdivision multiplexing approach to simultaneously generate and mix resonant and transmitting spectra. Taking advantage of Fano Resonances, we achieve high extinction ration with a small wavelength detuning in a low-Q cavity as in Figure and simultaneously provide the room to design modulator based on P-N junction as easily as in a single wire waveguide. We believe this proposed method will be an alternative for developing ultra-compact high-rate few-fJ/bit electrooptical modulators and provide a special insight into how practically employ Fano resonances.

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